Abstract: TI3.00005 : Exploring nuclear reactions relevant to Stellar and Big-Bang Nucleosynthesis using High-Energy-Density plasmas at OMEGA and the NIF

Author:

M. Gatu Johnson(MIT)

Thermonuclear reaction rates and nuclear processes have been explored
traditionally by means of accelerator experiments, which are difficult to
execute at conditions relevant to Stellar Nucleosynthesis (SN) and Big Bang
Nucleosynthesis (BBN). High-Energy-Density (HED) plasmas closely mimic
astrophysical environments and are an excellent complement to accelerator
experiments in exploring SN and BBN-relevant nuclear reactions. To date, our
work using HED plasmas at OMEGA and NIF has focused on the complementary
$^{\mathrm{3}}$He$+^{\mathrm{3}}$He, T$+^{\mathrm{3}}$He and T$+$T
reactions. First studies of the T$+$T reaction indicated the significance of
the $^{\mathrm{5}}$He ground-state resonance in the T$+$T neutron spectrum.
Subsequent T$+$T experiments showed that the strength of this resonance
varies with center-of-mass (c-m) energy in the range of 16-50 keV, a
variation that is not fundamentally understood. Studies of the
$^{\mathrm{3}}$He$+^{\mathrm{3}}$He and T$+^{\mathrm{3}}$He reactions
have also been conducted at OMEGA at c-m energies of 165 keV and 80 keV,
respectively, and the results revealed three things. First, a large cross
section for the T$+^{\mathrm{3}}$He-$\gamma $ branch can be ruled out as
an explanation for the anomalously high abundance of $^{\mathrm{6}}$Li in
primordial material. Second, the results contrasted to theoretical modeling
indicate that the mirror-symmetry assumption is not enough to capture the
differences between T$+$T and $^{\mathrm{3}}$He$+^{\mathrm{3}}$He
reactions. Third, the elliptical spectrum assumed in the analysis of
$^{\mathrm{3}}$He$+^{\mathrm{3}}$He data obtained in accelerator
experiments is incorrect. Preliminary data from recent experiments at the
NIF exploring the $^{\mathrm{3}}$He$+^{\mathrm{3}}$He reaction at c-m
energies of \textasciitilde 60~keV and \textasciitilde 100 keV also indicate
that the underlying physics changes with c-m energy. In this talk, we
describe these findings and future directions for exploring light-ion
reactions at OMEGA and the NIF. The work was supported in part by the US
DOE, LLE, and LLNL.

To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2017.DPP.TI3.5